An Appraisal of Phenotypic Diversity Among Hazelnut Wild Germplasm from Northwest Iran
الموضوعات :Ahmad Ershadi 1 , Javad Farrokhi Toolir 2 , Sona Hossein Ava 3 , Thomas Molnar 4
1 - Department of Horticultural Science, Bu-Ali Sina University, Hamedan, Iran
2 - Department of Horticultural Science, Bu-Ali Sina University, Hamedan, Iran |Kerman Agricultural and Natural Resources Research and Education Center, Agricultural Research, Education and Extension Organization (AREEO), Kerman, Iran
3 - Seed and plant Improvement Institute, Iranian Agriculture Ministry, Karaj, Iran
4 - Department of Plant Biology, Foran Hall, 59 Dudley Road, Rutgers University, New Brunswick, NJ 08901
الکلمات المفتاحية: Correlation analysis, Cluster analysis, genetic diversity, germplasm, Morphological Description,
ملخص المقالة :
The Fandogloo jungle is located in the Ardabil province of northwestern Iran, and contains the largest in situ germplasm collection of hazelnuts (Corylus avellana L.) in Iran. In this study, 12 quantitative and 21 qualitative traits of 70 wild hazelnut genotypes native to Fandogloo were studied, including traits of nuts, kernel and tree morphology. Results showed that, hazelnut genotypes from Fandogloo were phenotypically diverse with significant variation found across most traits studied. Interestingly, they had a smaller nut and kernel size and weight, compared to some hazelnut germplasm pools previously studied around the world, overall they exhibited a higher kernel to shell ratio. Results also showed, there were strong correlations between kernel length and kernel thickness (r=0.878), nut length and nut thickness (r=0.875), and kernel percentage and chlorophyll index (r=0.617). Positive correlations were also found between branching density and suckering (r=0.487) and between the curvature of the nut basal scar and size of the pistil scar (r=0.352). Principal component analysis of quantitative variables revealed that the first four principal components (PCs) accounted for 74.2% of the total variation. Regarding qualitative variables, the first nine PCs accounted for 64.3% of the total variation. Cluster analysis based on quantitative and qualitative traits resulted in a dendrogram with seven and eight main clusters, respectively. Some of the genotypes were not grouped according to their geographical distribution. Overall, this study revealed the presence of high phenotypic diversity in the hazelnut genotypes from Fandogloo region, supporting their breeding value for possible use in future.
Abdi H, Williams LJ (2010) Principal component analysis. Wiley Interdisciplinary Reviews. Computational Stat. 2, 433–459.
Anonymous (2018) Statistics of horticultural crops. Deputy Minister of planning and economic affairs of the ministry of Jihad agriculture. Iran. pp, 166. 1-10. [In Persian].
Amaral JS, Casal S, Rui M, Love M, Seabra RM, Oliveira BP (2006) Tocopherol and Tocotrienol Content of Hazelnut Cultivars Grown in Portugal. Journal of Agricultural Food Chemistry. 54, 1329-1336.
Ashrafi M, Azimi Moqadam MR, Moradi P, Shekari F, Mohseni Fard E (2018) Identification of drought tolerant and sensitive species of thyme through some physiological criteria. International Journal of Horticultural Science and Technology. 5(1), 53-63.
Aslamarz A, Vahdati K, Hasani D, Rahemi M, Leslie CA (2010) Supercooling and cold hardiness in the acclimated and deacclimated buds and stems of Persian walnut cultivars and genotypes. HortScience. 45 (11), 1-6.
Azimi MH, Alvijeh K, Zarei A (2018) Intervarietal hybridization and observation of heterosis in the new hybrids of Iris germanica. International Journal of Horticultural Science and Technology. 5(1), 65-79.
Bacchetta L, Rovira M, Tronci C, Aramini M, Drogoudi P, Silva AP, Solar A, Avanzato D, Botta R, Valentini N, Boccacci P (2015) A multidisciplinary approach to enhance the conservation and use of hazelnut (Corylus avellana L.) genetic resources. Genetic Resources Crop Evolution. 62, 649-663.
Balik HI, Beyhan N (2014) Clonal selection of Palazi hazelnut cultivar in Urdo district of Orduprovince Anadolu. Journal of Agriculture Science. 29(3), 179-185.
Boccacci P, Aramini M, Valentini N, Bacchetta L, Rovira M, Drogoudi P, Silva AP, SolarA, Calizzano F, Erdogan V, Cristofori V, Ciarmiello LF, Contessa C, Ferreira J, Marra FP, Botta R (2013) Molecular and morphological diversity of onfarm hazelnut (Corylus avellana L.) landraces from southern Europe and their role in the origin and diffusion of cultivated germplasm. Tree Genet Genome. 9, 1465-1480.
Boccacci P, Botta R (2009) Investigating the origin of hazelnut (Corylus avellana L.) cultivars using chloroplast microsatellites. Genetic Resource Crop Evolution Journal. 56(6), 851-859.
Bostan SZ, Islam A (1999) Determination of interrelationships among important nut quality characteristics on Palaz and Sivri hazelnut cultivars by path analysis. Turkish Journal of Agricultureand Foresty. 23, 371–375.
Cantini C, Cimato A, Sani G (1999) Morphological evaluation of olive germplasm present in Tuscany region. Euphytica. 109, 173-181.
Ebrahimian A, Khadivi-Khub A, Karim R (2015) Identification of superior walnut (Juglans regia L.) genotypes with late leafing and high kernel quality in Iran. Scientia Horticulturae. 193,195–201.
Emkani NaneKaran H, Motaji A, Akhavan R, Kiadaliri H (2013) Study the concomitant species of hazelnut and competitiveness of hazelnut species with their (Case Study: Ardabil Province Fandogloo forests). International Journal of Agriculture and Crop Sciences. 5(19), 2242-2246.
FAOSTAT (2018) Food and Agricultural Organization of the United Nations. Production crops. At: http:// faostat. fao. Org /site /567 /Desktop Default. Aspx Page ID=567.
Ferreira J, Garcia-Gonzales C, Tous J, Rovira M (2010) Genetic diversity revealed by morphological traits and ISSR markers in hazelnut germplasm from northern Spain. Plant Breeding. 129, 435-441.
Germain E (1997) Genetic improvement of the Persian walnut (Juglans regia L.). Acta Horticulture. 442, 21–31.
Glen WM, Holmstrom D (2012) Hybrid Hazelnut Evaluation Project on Prince Edward Island. Prepared for the P.E.I. Soil and Crop Improvement Association Agriculture Research Fund Project. 2, 1-26.
Gurrieri F, Audergon JM, Albagnac G, Reich M (2001) soluble sugars and carboxylic acids in ripe apricot fruit as parameters for distinguishing different cultivars. Euphytica. 117, 183–189.
Hassanzadeh Khankahdani H, Bagheri A (2019) Identification of genetic variation of male and female date palm (Phoenix dactylifera L.) cultivars using morphological and molecular markers. International Journal of Horticultural Science and Technology. 6(1), 63-76.
Hatami-Maleki H, Karimzadeh G, Darvishzadeh R, Sarrafi A (2011) Correlation and sequential path analysis of some agronomic traits in tobacco (Nicotiana tabaccum L.) to improve dry leaf yield. Australian Journal of Crop Science. 5, 1644-1648.
Hosseinova S, Pirkhezri M (2010) Evaluation of quantitative and quality characteristics in some hazelnut (Corylus avellana L.) Varieties in Karaj Climatic Conditions. Seed and Plant Production Journal. 26(3), 329-340. [In Persian].
Hosseinpour A, Seifi E, Javadi D, Ramezanpour S, Molnar TJ (2013) Nut and kernel characteristics of twelve hazelnut cultivars grown in Iran. Scientia Horticulturae. 150, 410-413.
Julian JW, Seavert CF, Olsen JF (2008) The costs and return of establishing and producing hazelnuts in the Willamette valley. Oregon State university extension service. 1-38.
Kasapligil B (1964) A contribution to the histotaxonomy of Corylus (Betulaceae). Adansonia .4, 43-90.
Koksal I, Tuna Gunes N (2008) Descriptors for hazelnut (Corylus avellana L.) Bioversity International/ FAO/ CIHEAM. 1-64.
Korac M, Cerovic S, Golosin B, Miletic R (1997) Collecting, evaluation and utilization of walnut (Juglans regia L.) in Yugoslavia. Plant Genetic Resources Newsletter. 111, 72–74.
Liang W, Dong D, Wang W, Dong F, Liang L (2008) Studies on hazelnut hybridization breeding of (C. heterophylla × C. avellana) in china. 7 th International congress on hazelnut, 23-27 June Viterbo, Italy. pp. 25.
Mars M, Marrakchi M (1999) Diversity of pomegranate (Punica granatum L.) germplasm in Tunisia. Genetic Resources and Crop Evolution. 46,461–467.
Miletić R, Mirtović M, Rakakićević M, BlagojevićŽaklina M (2007) The study of populations of hazelnut (C. avellana L.) and Turkish hazelnut (C. colurna L.) and their selection Karaklajić- Stajić. Genetica. 39(1), 13-22.
Mehlenbacher SA (1991) Hazelnuts (Corylus). In: Moore JN, Ballington JR (ed.). Genet resource temperate fruit nut crops. International Society of Horticultural Science, Wageningen, The Netherlands. pp.789–836
Menesattia P, Corrado C, Pagliaa G, Pallottinoa D, Andreab S, Rimatoria V, Aguzzic J (2008) “Postharvest Technology Shape-based methodology for multivariate discrimination among Italian hazelnut cultivars”. Agricultural Engineering Research. 16, 128-145.
Mohammadi SA, Prasanna BM (2003) Analysis of genetic diversity in crop plants-salient statistical tools and considerations. Crop Science. 43, 1235-1248.
Mohammadzadeh M, FattahiMoghaddam MR, Zamani Z, Kadivi-Khub A (2014) Genetic identity and relationships of hazelnut (C. avellana L.) landraces as revealed by morphological characteristics and molecular markers. Scientia Horticulturae. 167,17-26.
Monastra F, Raparelli E (1997) Clonal selection of Tonda Gentile Romana. Acta Horticulture. 445, 39-44.
Mosivand M, Hassani D, Payamnour V, JafarAghaei M (2012) Comparison of tree, nut, and kernel characteristics in several walnut species and inter-specific hybrids. Crop Breeding Journal. 3(1), 25-29.
Mratinić E, Fotirić-Akšić M (2012) Phenoty pic diversity of apple (Malus sp.) germplasm in south Serbia. Brazilian Archives of Biology and Technology. 55, 349-358.
Nejatian M, Hosseinova S, Javadi D (2012) Collection and preliminary evaluation of some hazelnut Genotypes of Iran. Journal seed and plant improvement. 28(1), 115-132.
Nikolic D, Rakonjac V, Milatovic V, Fotiric M (2010) Multivariate analysis of vineyard peach (Prunus persica L.) Batsch.) germplasm collection. Euphytica. 171, 227-234.
Ozdemir F, Akinci I (2004) Physical and nutritional properties of four major commercial Turkish hazelnut varieties. Journal of Food Engineering. 63, 341–347.
Pourkhaloee A, Khosh-Khui M, Arens P, Salehi H, Razi H, Niazi A, Afsharifar A, Van Tuyl J (2017) Genetic Diversity and Population Structure of
Iranian tulips revealed by EST-SSR and NBS-LRR Markers. International Journal of Horticultural Science and Technology. 4(2), 167-82.
Rushforth K (1999) Trees of Britain and Europe. Collins. pp. 1006-1052.
Srivastava K, Khursheed KA, Zargar A, Shyma RS (2010) Genetic divergence among Corylus colurna genotypes based on morphological characters of hazelnut. Biodiversity: Research and Conservation. 17, 13-17.
Thompson MM, Lagerstedt HB, Mehlenbacher SA (1996) Hazelnuts. Janick J, Moore JN, (ed.). Fruit Breeding.Wageningen Press, the Netherlands. pp. 125-184.
Yao Q, Mehlenbacher SA (2000) Heritability, variance component and correlation of morphological and phonological traits in hazelnut. Plant Breeding. 119, 369-381.